Bone anchored hearing implant/aid (BAHI/BAHA) surgery

OPEN ACCESS ATLAS OF OTOLARAYNGOLOGY, HEAD &
NECK OPERATIVE SURGERY
BONE ANCHORED HEARING IMPLANT/AID SURGERY (BAHI/BAHA)
Malou Hultcrantz
Bone anchored hearing implants/aids
(BAHI/BAHA) utilise a bone anchored
hearing aid system to assist people with
conductive hearing loss who cannot use
traditional hearing aids. It was introduced
in the 1970´s in the field of dentistry by
Swedish Professor Per-Inge Brånemark
who implanted titanium dental fixtures in
the jaw. He then proceeded to develop
titanium implants to anchor hearing aids to
the skull with Dr Anders Tjellström, a
Swedish ENT surgeon 1. The system comprises an osseointegrated implant, an
abutment, and a processor (Figures 1a, b).
Figure 1a: Titanium fixture anchored in
the bone with an abutment attached. The
processor is connected to the abutment
with a snap coupling.
Figure 1b: Titanium fixture with abutment
The fixture uses the characteristics of
titanium to osseointegrate into bone. Bone
cells (osteoblasts) adhere to the titanium
surface of the implant with-out any other
cells or capsules developing in-between.
The biocompatibility of the metal is dependent on the titanium oxide layer on the
surface of the implant and the lack of
tissue interface between the bone and the
titanium, all of which improve bone con-
duction of sound 2. The surface and shape
of the implant and its abutment have since
been refined. Different surfaces of the
abutment have been tested and refinements
continue.
Surgical techniques continue to evolve.
Historically there was a long tradition of a
“skin thinning technique”. The idea was to
minimise the depth of the skin down to the
periosteum and to remove all subcutaneous
tissue as well as hair roots to avoid bacterial penetration. The ideal thickness of the
skin was recommended to be 0.2-0.5mm.
In the early days a full skin transplant
replaced the removed tissue and the surgical procedure took up to 5 hours 3. With
new tools and new surgical flap techniques
(semicircular flaps, dermatome, pre-drawn
fixtures/abutments, one-step surgery etc.)
the operating time was reduced to about 1
hour. The dermatome was introduced in
2006 to create a skin flap of predesigned
thickness - a measure that also reduced the
surgery time - but with the drawback that
flap necrosis occurred more commonly 4.
The surgical procedure was further simplified by changing the surgical tools and
implant design. Further refinements were
introduced in 2007 when the skin thinning
technique was replaced by a “non-skin
thinning” or “tissue preserving” technique. Nowadays one simply makes small
openings in the skin without skin reduction
by punching a hole through which the
abutment is externalised 5. This requires
longer abutments which are commercially
available. This technique has reduced the
surgical time to 10-15 min. The situation
has also changed over the years in paediatrics; now the implantation is done in a
single step in children 6. The most recent
development is implants placed under the
skin with the processor connected via a
magnet.
Physiology of bone conduction
The BAHA/BAHI employs direct percutaneous coupling of sound vibrations from a
transducer to a titanium implant anchored
in the skull. Hearing through direct bone
conduction is defined as “sound transmission via bone conduction without the skin
and soft tissue being part of the vibration
transmission pathway between the transducer and the skull bone.” Direct bone
conduction provides a sensitive input for
vibrations to the skull, high-quality transmission of sound with sufficient gain and
power output, and also improved patient
comfort.
be of value when there is only one
functioning cochlea with SSD; sound
waves from the processor on the deaf side
are transmitted to the contralateral functioning cochlea (Figure 2). However even
though binaural hearing will not develop if
implanted in adulthood, it might be possible to achieve binaural hearing if the implant is placed early in childhood.
It is the cochlear function that is
important; if sensorineural hearing is sufficient, then a bone-conduction hearing aid
can transmit sound to the cochlea. The
degree of conductive hearing loss is of
minor importance since the bone-conducted sound bypasses the middle ear; the
benefits of BAHA/BAHI are therefore
independent of the external and middle
ears 7.
When an acoustic stimulus is presented to
one ear there is a reduction in intensity of
the sound perceived by the opposite ear.
This phenomenon is called interaural
attenuation. For air conduction, the reduction approximates 35dB, but for bone
conduction, it is <10dB. Consequently the
sound delivered with a bone-anchored
solution is delivered to the opposite
cochlea without much loss.
Hearing with two ears (binaural hearing)
makes it possible to localise the source of a
sound and to hear better in noisy environments. If one has only one hearing ear i.e.
single sided deafness (SSD) or ear canal
atresia etc., the absence of a time lag
between sounds reaching each ear means
that one’s ability to localise the source of a
sound is lost. The BAHI has been shown to
Figure 2: Sound conduction in the case of
two normal cochleae (above) or with only
a functioning right cochlea and left SSD
BAHA/BAHI
The BAHA/BAHI has 3 parts (Figure 3):
1. Titanium fixture introduced into the
skull behind and above the pinna
2. Skin-penetrating abutment attached
(screwed) to the fixture
3. Conventional microphone and amplifier (processor) connected by a snap
coupling to the abutment
2
Figure 3a: Cochlear osseointegration system with coupling inside the abutment
Figure 4: Classification of hearing loss
Degree of HL
Normal
Slight
Mild
Moderate
Moderately severe
Severe
Profound
Figure 3b: Oticon system: Left-to-right:
Sound processor; Coupling; Screw; Abutment; Implant. The coupling is on the outside of the abutment
Patient selection
All patients who need a hearing aid but
cannot have it fitted into the ear canal may
benefit from a BAHI - within certain limits
depending on the patient, implant and
processor. Figure 4 and Table 1 and below
show one of the more commonly used
classification systems (degree of hearing
loss = severity of loss). Many vendors
recommend BAHI as a solution for
patients with moderate-to-severe mixed
hearing loss.
Hearing loss (dB HL)
–10 to 15
16 to 25
26 to 40
41 to 55
56 to 70
71 to 90
91+
Table 1: Classification of hearing loss
(HL)
To identify a suitable patient requires an
audiogram with classification of type of
hearing loss and at least a 3-4 weeks trial
of a BAHI on a soft band at home and in
working situations. If a patient is still
interested to proceed after such a trial,
surgery can be planned. This selection
process hopefully reduces the number of
future nonusers. The benefit is limited by
inner ear “cochlear” function. However,
even if a patient does not fall within the
recommended domain of hearing loss, it
may be worth a trial of a BAHI with a
headband for 3 weeks. Some patients do
benefit even if it is difficult to predict
according to existing hearing tests.
3
Indications for BAHI include:
1. Conductive hearing loss, when using
conventional hearing aids is impossible (ear canal problems, allergy to
hearing aid material), or when hearing
aids are contraindicated (ear must be
kept dry) or ineffective
2. Mixed hearing loss (both conductive
and sensorineural hearing loss)
3. Chronic otitis media, or chronic suppurative otitis media with otorrhoea (impossible to use a conventional hearing
aid)
4. Congenital microtia or canal atresia (no
ear canal for fitting)
5. Chronic otitis externa (skin problems)
6. Discomfort with conventional hearing
aids (pain, moist, recurrent infection)
7. Ineffective conventional hearing aids
due to considerable air-bone gap (not
enough ”gain”, bad occlusion or feedback)
8. Single sided deafness (SSD); note that
BAHI devices do not restore binaural
hearing
9. Bilateral and single sided conductive
hearing loss (CHL)
10. Bilateral hearing problems/infections
where surgery is planned for the two
ears at different times (hearing while
waiting)
Figure 5: Hearing loss area for patients to
benefit from Ponto processors (Oticon) &
Baha 4 (Cochlear).
Selecting an appropriate BAHA/BAHI
Different devices are recommended in
accordance with hearing loss and individual preference. General examples are
given below.
Figure 5 illustrates the recommended hearing loss area for patients to benefit from
Ponto processors & BAHA 4. Figure 6
illustrates the recommended hearing loss
for patients to benefit from a more powerful Ponto Pro Power ® (Oticon) 8 & Baha
3 Power ® (Cochlear) 9.
Figure 6: Ponto Pro Power® (Oticon) 8 &
Baha 3 Power Sound Processor ®
(Cochlear) 9
Figure 7 illustrates the recommended hearing loss area for patients to benefit from a
BAHI Cordell, which is the most powerful
device and is body worn.
4
dermatome or with a knife and to reduce
the subcutaneous tissue down to periosteum. This can also be achieved by totally
removing a circle of skin for a new skin
graft. The skin is thinned and hair follicles
reduced; the hole in the skull bone is
drilled; the implant with pre-drawn abutment is introduced; a hole is punched
through the thinned skin where the
abutment is externalised; and the wound is
closed and dressed.
Figure 7: BAHI Cordell, the most powerful
device and body worn
Surgical procedure
Older techniques that employ skin thinning
are still used in many countries. However
newer skin preservation techniques have
proven to be safe in the long-term and have
significant benefits 10 i.e. reduced surgical
time; quicker healing; earlier loading of the
processor; less peri-implant infections; no
numbness around the implant site; and
normal hair cover (Figure 8).
Figure 8: Normal hair cover 5 years after
surgery
Linear incision with tissue preservation
Most adults cases are done under local
anaesthesia as an outpatient procedure
with the head turned to the side;
general anaesthesia can be done with a
laryngeal mask (Figure 9)
Skin thinning technique
The older skin thinning technique (dermatome and variety of flap techniques) has
been so frequently used all over the world
and will only be briefly described. It is
often performed under general anaesthesia
and the surgical time about 45 min. The
principal step is to raise a flap either with a
Figure 9: Patient anaesthetised with
head in lateral position
5
Clean the skin and drape the surgical
area (Figure 10)
Figure 12: Cut a hole in the superior
drape for the ear and surgical field
Figure 10: Washing and then redrawing so that the designated spot is
visible
Shave a small part of the surgical area
if necessary
Mark the position of the implant with
dye e.g. methylene blue, approximately
5.5cm behind and above the opening of
the external ear canal (Figure 11)
Figure 11: Blue mark indicates position of implant
Figure 13: Cut a hole in the inferior
drape for the ear and surgical field
Figure 14: U-shaped sheets taped……
Take care to choose the right position
if the patient wears glasses so that the
processor will not interfere with the
earpiece of the glasses ; if an otoplasty
is to be done in the future, the skin
incision is placed in a more posterior
location (Figure 44)
Drape the patient (Figures 12-17)
Figure 15: ….and pasted to the skin
6
Figure 16: Apply an adhesive transparent plastic sheet (optional)
Figure 19: Attach the irrigation solution
Figure 17: Final view of draped field
Figure 20: Set the drill speed
Prepare the drill system (Figures 1822)
Figure 21: Check the drill and integrated irrigation system
Figure 18: Mount the drill irrigation
tubing to the drilling machine (if such
system is not available irrigate with a
syringe filled with NaCl to cool the
drilling of the bone
Figure 22: Drill bits
7
Set out the
(Figure 23)
required
instruments
Figure 25 : Vertical 4cm incision down
to bone
Figure 23: Instruments required
Measure the skin thickness either now
(or later as in Figure 27) with a needle
through the blue marked spot, mark the
depth and measure with a ruler
Make a straight 30-40mm linear incision down to periosteum in front of the
spot as indicated in Figures 24, 25
Obtain haemostasis (Figure 26)
Incise the periosteum
Figure 26: Use electrocautery for
haemostasis
Measure the skin thickness (Figure 27)
Set the drill at 2000rpm (Figure 28)
Figure 27: Measure the skin thickness
Figure 24: Straight 30-40mm linear
incision down to periosteum
8
Widen the drill hole with a “countersink” burr, still at 2000 rpm drill speed
(choose a 3 or 4 mm countersink depending on the depth of the burr hole)
(Figures 31, 32)
Figure 28: Drill setting for initial drill
holes
Drill a 3mm deep hole in the bone in
the selected place with a high speed
drill (2000rpm) with a plastic “stopper”
on (Figures 29, 30)
If there is still bone in the bottom of
the hole, remove the plastic stopper on
the drill piece and continue drilling
until the next stop is reached and a 4
mm depth is achieved. This allows a
4mm fixture to fit into the hole with
good stability for the abutment (Figure
29, 30)
Figure 31: One hole has been enlarged
with the countersink drill (child)
Figure 32: Both holes have been enlarged (child)
Figure 29: 3 mm drill bit with plastic
“stopper”
Figure 30: Note: 2nd hole is drilled in
children for a "sleeping fixture"
Select the correct fixture according to
the drill hole (3 or 4 mm) and the
predrawn correct abutment according
to the skin thickness (6-12 mm long)
Set the drill at a low speed and at a
power setting of 40-50 Ncm (adults,
and ca 25 Ncm for children) (Figure
33)
Set the drill at a low speed and at a
power setting of 40-50 Ncm (Figure
34)
Screw the fixture into place (Figure
35)
9
Figure 33: Drill setting for inserting
the fixture
Figure 36: Punching a hole in the skin
Figure 34: Fixture screwed into bone
Figure 37: Punch a hole through the
skin and apply a cover screw to the 2nd
fixture in children
Figure 35: 2nd fixture being inserted
(child)
Punch a hole in the skin at the marked
place with a 5mm diameter skin punch
(Figures 36, 37)
Externalise the abutment through the
hole (Figure 38)
Close the skin with resorbable subcuticular sutures (Figure 38, 39)
Figure 38: Pass the abutment through
the hole in the skin
10
Figure 39: Taping the incision
Figure 42: Fluffed gauze is placed over
the wound
Attach a healing cap to the abutment
(Figure 40)
Figure 43: Apply a head bandage
Figure 40: A healing cap is applied
Gently wind gauze impregnated with
antibiotic ointment around the abutment and under the cap (Figure 41)
Remove the healing cap after 7-10 days
together with the gauze
The processor can be loaded to the
abutment after another 2-4 weeks 5, 11
Video of surgical technique of linear
incision
with
tissue
preservation:
https://www.youtube.com/watch?v=7lQsa
V6GTA8
Biopsy punch technique (Figures 44a, b)
Figure 41: Terracortril ribbon gauze
rolled under the healing cap
Mark the implant site
Measure the skin thickness with a
needle
Inject local anaesthesia
Remove the skin and soft tissue with a
wide punch down to periosteum
Place fluffed gauze over the wound and
apply a head bandage (Figures 42, 43)
11
Drill a hole in the bone through the
punch hole to an appropriate length (3
or 4mm)
Introduce the pre-drawn fixture with an
abutment of the correct length
No suturing is required unless a very
wide punch (12mm) has been used 12
Note: The emissary veins in the bone
can bleed briskly when drilled into, so
always be prepared for this event e.g.
open the skin wider, bone wax etc.
Surgical procedures in children
If a child is born with severe hearing loss,
single or double-sided atresia or SSD, it is
recommended to refer the child to an audiological centre early. Testing with a
BAHI on a soft band can then be done and
the BAHI fitted later (Figure 45).
a
Figure 44a: Removing skin and soft tissue
(also the periosteum) with a wide punch
Figure 45: BAHI on a soft band
b
Figure 44b: Abutment in place (With
permission from Oticon Medical)
With atresia, outer ear reconstruction is
recommended when enough rib cartilage
has developed at the age of 5-10 years.
Outer ear canal reconstruction can be
considered when children are able to
decide for themselves (14-16 years of age).
If a new ear canal has been surgically
constructed the child needs to see an ENT
specialist every 6-12 months to clean the
ear canal to avoid retention of debris and
development of cholesteatoma. There is a
trend today to avoid the difficult surgery to
reconstruct the ear canal, since the results
have not been good enough, and instead to
reconstruct an outer ear in a cosmetically
acceptable way and to use a BAHI for
hearing. Children with double-sided atresia
must use a BAHI on a soft band from a
young age (3 months) for language acqui12
sition, whereas others should start as soon
as possible, and always 3-4 weeks before a
decision is made to operate.
Children with single-sided atresia benefit
from training the hearing pathways early
on the atretic side. Previously no rehabilitation was given to these children since
they developed speech normally. However,
in the busy society of today it has been
shown that these children will have
problems later on and that the earlier they
are fitted with a BAHI the better. A
headband at an early age gives the child
the possibility to get used to binaural
hearing. Reports show that as many as 1/3
of these children need to repeat one year at
school and that every other child needs
extra resources during schooling. Some
children with single-sided atresia, even if
they do not have other syndromes, will
never develop strategies to cope with their
hearing handicap 13.
A permanent fixture and abutment for the
bone conducting hearing aid is easier to
utilise for a child than a headband and also
gives better hearing. The time at which to
introduce the permanent fixture can be
decided when the skull bone thickness is
>2.5mm, which is usually around the age
of 2,5 - 3 years.
trauma or infection (Figure 46). (In such
cases one simply needs to punch through
the skin overlying the sleeping fixture as
the implant is already osseointegrated).
The 2 fixtures are introduced and the skin
is closed. The system is left undisturbed
for 2-3 months for osseointegration to
occur. At the 2nd surgical stage the skin
over the selected fixture is punched out
and the abutment is introduced under
general anaesthesia. The processor is
loaded quite soon thereafter 6 (Figure 47).
It is recommended that the child uses a
“safe line” to attach the processor to
his/her clothes in order not to lose the
processor.
Figure 46: Two fixtures placed in the skull
BAHI surgery in children is usually done
under general anaesthesia. The procedure
can be performed as a 1-stage or a 2-stage
procedure depending on how thick the
skull bone appears to be at surgery. If the
bone is >2.5-3mm thick, then surgery can
be performed as a 1-stage procedure in the
same manner as described for adults. If the
skull is thinner, a 2-stage procedure is
preferable.
Two fixtures are usually placed in the bone
in children; one is used with the abutment
and the 2nd as a sleeping “rescue fixture” to
be used if the 1st implant is removed after
Figure 47: Processor placed a bit further
back due to pending outer ear reconstructtion
13
Loading the sound processor
Grade 4: Overt signs of infection resulting
in removal of the implant
Two manufacturers currently produce
BAHA/BAHI fixtures and abutments. The
Cochlear processor only fits onto the
Cochlear abutment 8, while both the Oticon
and Cochlear processors fit onto the Oticon
abutment 9 allowing the patient and audiologist the flexibility to select the processor
best suited to the individual’s hearing loss.
Once the fixture has osseointegrated after
2-3 weeks, the audiologist or audiology
technician fits the processor according to
the individual audiogram using the
corresponding software program. Usually
2-3 appointments with the audiologist are
required to adjust and tune the processor to
optimise the sound perception.
New better processors are constantly being
released with new features e.g. streamers,
that make it possible to direct sound from a
mobile telephone directly to the aid.
Complications
Problems encountered with percutaneous
(implant passes through skin) systems
include peri-implant infection, loss of the
abutment (infection or trauma), cosmetic
factors, skin numbness and the fact that the
skin needs lifelong daily care etc.
Peri-implant infection
Peri-implant infections occur commonly
around the abutment (Figure 48). The
Holgers classification system grades soft
tissue reactions at the implant site 14:
Grade 1: Redness with slight swelling
around the abutment
Grade 2: Redness, moistness and moderate
swelling
Grade 3: Redness, moistness and moderate
swelling with tissue granulation around the
abutment
Figure 48: Peri-implant infection
Infection can be avoided if the correct skin
care is applied daily. Cleaning the skin
around the abutment is an important task
for the patient who has to learn the signs
and properties of their skin. Recommended
tools for skincare are a soft toothbrush to
clean the abutment site, water and soap,
the correct type of hair shampoo and an
ointment if the skin is dry. If infection is
noted, then more intensive cleaning is
necessary and an ointment with antibiotics
should be applied. Cauterising agents like
silver nitrate can be used on the skin for
granulation tissue around the abutment and
oral antibiotics can be prescribed if a
bacteriological sample shows any growth.
The abutment has to be removed only if
the infection persists (uncommon) to get
rid of the infection and to allow the skin to
heal. The osseointegrated fixture can be
used again at a later stage. Such infections
are less troublesome and recurrent if new
skin preserving surgical techniques are
used.
Skin pockets
The area close to the abutment can deepen,
creating a skin pocket. Such pockets can be
difficult for a patient to clean and meticulous skin care necessary in such cases is
difficult for health care centres to provide.
14
Deep skin pockets are seldom seen with
the newer surgical techniques.
performed in adults. In children the sleeping fixture can be used for fixation of a
new abutment.
Poor osseointegration and fixture loss
Skin overgrowth (Figure 48)
This can be due to infection, biological
factors, poor bone quality etc. and starts
early after implantation or later after a first
successful osseointegration. Surgical revision is required once the skin has healed
after removal of the fixture.
With earlier flap techniques when the skin
was extensively thinned and only 5.5mm
abutments were available, skin at times
overgrew the abutment and prevented good
connection with the processor.
Flap necrosis
This is seen if a procedure creating a thin
skin flap has been used, and delays healing. This problem is not often encountered
if the skin is preserved.
Numbness around the abutment
If wide subcutaneous tissue removal is
done as with the surgical flap technique,
nerves supplying the skin are destroyed
and permanent numbness in an area of up
to 10cm may ensue. Numbness is a minor
issue and is seldom seen with the modern
techniques; it may be confined to only a
small area around the abutment.
Deep pain
Hyperaesthesia sometimes occurs around
the abutment. If deeper pain occurs from
bone it may be necessary to drill out the
osseointegrated fixture.
Traumatic loss of abutment/fixture
Any direct trauma to the head and the
implant area may lead to a loss of the
implant. The skin heals over the fixture
extremely quickly (1-2 days). If only the
abutment is lost, a new abutment can be
introduced as an outpatient procedure under local anaesthesia through a newly
punched hole. If the entire fixture is lost,
then a new surgical procedure has to be
Figure 48: Skin overgrowth over the
abutment which makes it impossible to use
the processor
In children, new bone formation under the
reduced skin was common and caused skin
overgrowth. Another surgery was then
necessary to thin the skin again and
eventually drill some bone away. Skin
overgrowth is less problematic today as
skin thinning is not done and with the
availability of a range of abutments that
allow one to unscrew an abutment that is
too short and replace it with a longer one;
this can be done also in children as an
outpatient procedure without any local
anaesthesia.
New implants on the market
Four new implants were recently released
as described below, and another is soon to
be released (BCI, Oticon) that is implanted
15
under the skin in order to avoid skinrelated problems.
Sophono Alpha 2® (Sophono): This is a
magnetically coupled bone anchored hearing device without an external abutment 15.
The abutment is placed under the skin
(Figure 50).The system can only be used
for mild hearing loss.
Baha 4 Attract® (Cochlear): The sound
processor attaches to an external magnet,
which transmits the sound to an internal
magnet hidden under the skin. The magnet
is attached to the implant, which delivers
vibrations through the skull to the cochlea.
The surgery can be performed under local
anaesthesia. The implant is not MRI
compatible 9 (Figure 52).
Figure 50: Sophono Alpha 2®
Figure 52: Baha 4 Attract®: The two
implant components are deep to skin
Bonebridge® (MedEl): This is an active
BAHI placed under the skin. The vibrator
(9mm diameter) is buried deep into the
mastoid bone and requires extensive
drilling to be fitted. The vibration is transferred through 2 screws that attach the
vibrator to the bone. Patients have to have
a CT scan performed before surgery to
determine whether the mastoid bone can
accommodate the implant. It is MRI
compatible 16 (Figure 51).
SoundBite ® (Sonitus Medical): This is a
non-surgical hearing solution using bone
conduction transmission via the teeth 17
(Figure 53).
Figure 53: Soundbite® attached around
the teeth
Figure 51: The Bonebridge® vibrator is
placed into the mastoid
Even with the many new innovations to
come, the standard BAHI that penetrates
the skin will still have its place as it is a
quick surgical procedure performed under
16
local anaesthesia, and is a reliable aiding
solution.
Instructional video
Linear incision with tissue preservation
surgery technique:
https://www.youtube.com/watch?v=7lQsa
V6GTA8
References
1. Tjellström A, Håkansson B, Lindström
J, et al. Analysis of the mechanical
impedance of bone-anchored hearing
aids. Acta Otolaryngol 1980; 89: 85-92
2. Albrektsson T, Brånemark PI, Hansson
HA, et al, Osseointegrated titanium
implants: requirements for ensuring a
long-lasting direct bone-to-implant
anchorage in man. Acta Orthop Scand
1981; 52: 155-70
3. Håkansson B, Lidén G, Tjellström A,
et al. Ten years of experience with the
Swedish
bone-anchored
hearing
system. Ann Otol Rhinol Laryngol
Suppl. 1990 Oct;151:1-16
4. Stalfors J, Tjellström A. Skin reactions
after BAHA surgery: a comparison
between the U-graft technique and the
BAHA dermatome. Otol Neurotol.
2008 Dec;29(8):1109-14
5. Hultcrantz M. A clinical trial using the
bone-anchored hearing aid (Baha)
method without the skin thinning step.
Otol & Neurotol 2011;32(7):1134-9
6. Lanis A, Hultcrantz M. Percutaneous
osseointegrated implantation without
skin thinning in children: A retrospecttive case review. Otol Neurotol 2013;
34 (4):715-22
7. Eeg-Olofsson M, Stenfelt S, Taghavi
H, et al. Transmission of bone conducted sound - correlation between hearing
perception and cochlear vibration.
Hear Res. 2013 Dec;306:11-20
8. http://www.cochlear.com/wps/wcm/co
nnect/sv/home
9. http://www.oticonmedical.com/
10. Hultcrantz M, Lanis A. A five year
follow-up on the osseointegration of
bone-anchored hearing aid implantation without tissue reduction. Otol
Neurotol. 2014 (In press)
11. Hultcrantz M. Linear incision surgery
with tissue preservation. Educational
film 2012
www.youtube.com/watch?v=7lQsaV6
GTA8
12. Goldman RA, Georgolios A, Shaia
WT. The punch method for bone
anchored hearing aid placement. Otolaryngol Head Neck Surg 2013;148:87880
13. Cho Lieu J. Speech, language and
educational consequences of unilateral
hearing loss in children. Acta Otolaryngol Head Neck Surg, 2004;130:524-30
14. Holgers KM. Soft tissue reactions
around clinical skin-penetrating titanium implants. PhD thesis, ISBN 91628-1334-X. Gothenburg University,
Gothenburg, Sweden, 1994
15. http://sophono.com/
16. http://www.medel.com/int/vbb
17. http://www.sonitusmedical.com/produc
t/
Author
Malou Hultcrantz MD, PhD
Professor
Department of Otolaryngology
Karolinska University Hospital
Stockholm
Sweden
[email protected]
Editors
Claude Laurent MD, PhD
Professor in ENT
ENT Unit
Department of Clinical Science
University of Umeå, Umeå, Sweden
[email protected]
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De Wet Swanepoel PhD
Professor
Department of Communication Pathology
University of Pretoria
Pretoria, South Africa
[email protected]
Johan Fagan MBChB, FCORL, MMed
Professor and Chairman
Division of Otolaryngology
University of Cape Town
Cape Town, South Africa
[email protected]
OPEN ACCESS ATLAS OF
OTOLARYNGOLOGY, HEAD &
NECK OPERATIVE SURGERY
www.entdev.uct.ac.za
The Open Access Atlas of Otolaryngology, Head &
Neck Operative Surgery by Johan Fagan (Editor)
[email protected] is licensed under a Creative
Commons Attribution - Non-Commercial 3.0 Unported
License
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